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As you know, I love receiving your questions and I am always thinking of different ways to answer them. Some you will find in my regular column in the Irish Examiner, some I answer here on the blog, in written, video and info-graphic form.

Here is something a little bit different and I am hoping to make it a regular thing, so please let me know what you think and keep those questions coming!

Are all raindrops the same size?

In order to answer this question we need to first understand how raindrops are formed. And that story starts right down here on Earth. We have lots of water in the form of rivers, lakes and seas and when this water heats up it changes into a gas, called water vapour which rises up into the air.

The sky actually has lots of bits floating around in it – like dust and smoke particles. The water vapour tends to form tiny droplets of water around these little specks of dust and smoke and these droplets come together to make clouds.

At this stage the tiny drops are light enough to stay in the sky, but, as the cloud fills up with more and more of them they tend to start to bumping off each other and as they do they join together to form bigger droplets. Eventually they get so big and heavy that they can no longer stay in the cloud and they drop down towards the Earth as rain.

A water droplet needs to be at least ½ mm in diameter before it will fall as a raindrop.

Depending on how many droplets have joined together to make that raindrop, we already have drops of different sizes falling from the clouds.

What shape doe you think the raindrops are? Teardrop shaped maybe? No, not at all! Although raindrops are usually depicted in this teardrop shape they actually start off as nice round spheres. They have lots of forces acting on them, like surface tension which acts on the surface of the drop keeping it in that nice round shape.

As the rain drops fall they experience other forces too like air pressure. As it pushes from below and above the rain drops get squished into sausage like shapes until they eventually split into a number of small drops of various sizes and these are what fall to the ground.

So, are all raindrops the same size? Definitely not!

And they are not all teardrop shaped either.

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A big thanks to Ewan for sending in this question. Remember to keep sending in your questions. You can leave them in the comments below.

I’d love to know what you think of this video, there are lots of improvements I want to make and I’d love your comments and feedback.

We were lucky enough to go on a family skiing holiday this January…. sunlight, snow, fresh air, exercise, skiing and just an all round great experience. I have asked my three children the best things about the holiday and here are their responses….

So a mixed bag of responses there but with the one common denominator… THE SNOW!!!! And who could blame them, I loved it too! Especially on our last day, the weather got colder and we had a wonderful day of snow. At lunch time our entire group (15 of us in total) took the cable cars to the top of the mountain for lunch. The snow up there was thick and deep and as it fell on us we all remarked on the beautiful snow flakes… each one a perfect crystal, large enough to see the tiny branches coming off each arm of the structure. So the inevitable question came from the children….

……………………..”WHY DOES THE SNOW AT HOME NOT LOOK LIKE THIS?”

A Dendrite Snow Crystal

In order to answer this question we need to understand how snow is made and what can influence this process! We also need to understand the different shapes that snow can take!

So firstly HOW IS SNOW MADE?…

Snow is made much in the same way as rain, it is created from the moisture that makes up clouds. Moisture from the earth (seas, rivers, lakes, puddles etc) is constantly EVAPORATING (changing from a liquid to a gas form). This water vapour (gas) is picked up by warm air and carried to the sky where it forms clouds. When the temperatures get cold enough the water vapour turns into ice crystals that form around tiny particles of dust or dirt in the atmosphere. These ice crystals fall to the earth as snow.

So what is the difference between SNOW CRYSTALS and SNOW FLAKES?

A snow crystal is a single crystal of ice that can come in many different shapes. A snow flake is the term we are more familiar with – it can refer to one snow crystal or a group of snow crystals all grouped together. Some snow flakes can contain a clump of hundreds of tiny snow crystals.

WHAT ARE THE DIFFERENT SHAPES A SNOW CRYSTAL CAN BE?

When you think of the shape of a snow flake what do you think of? Do you think of the lovely star like ones with six branches just like the photo above? This shape of snow crystal is called an HEXAGONAL shape (having six sides) but finding these in such perfect condition is actually quite rare. With melting and refreezing, wind interference and snowflake collision most snowflakes we see are much more irregular structures. The snow crystal shown above is a STELLAR DENDRITE which means a star-shaped snow crystal with six branches that have lots of side-branches coming off them (dendrite means tree-like). More often than not snow crystals are small, NEEDLE, COLUMN or FLAT PLATE shaped and clumped together into one snow flake. This is certainly what we are more used to in Ireland when it snows. The array of shapes and sizes of snow flakes is really well described in this guide to Snowflakes.

This is what we saw in Austria!!

The lovely snowflakes that we saw on the top of the mountain in Austria were particularly intricate and beautiful. I would say they were FERNLIKE STELLAR DENTRITES and if you are thinking of skiing these are ideal. There is so much side branching that they look like ferns. Although these snow crystals are the largest that we see they are actually individual snow crystals which makes them all the more spectacular. They are often 5 mm or more in diameter and are clearly visible to the naked eye! So we were really lucky to see these lovely snow flakes. These crystals are very light and make the best powdery snow!

WHAT INFLUENCES THE SIZE, SHAPE AND SYMMETRY OF A SNOWFLAKE?

So what factors influence the distinctive shape of each snow crystal? Well for starters there is the temperature at which they form – snow crystals start to form when the cloud temperature reaches or drops below freezing (zero degrees Centigrade (C)); the amount of dust or dirt particles available also effects snow formation. Then there is the location of the clouds in which the snow crystals form… in general snow flakes are larger when formed in high clouds compared to snowflakes from lower clouds. This factor links with the length of time the snow flake takes to fall to the ground along with the air temperature as it falls and with how many collisions the snow flakes might encounter. Snowflakes will often heat and cool as they drop due to differences in air temperature, this often leads to large snowflakes as they become more “sticky” when they melt at the edges, allowing them to clump together as they collide and refreeze. Other weather factors such as humidity (how much water vapour is in the air) and the wind speed all contribute to the final size and shape of the snowflake formed.

Taking these factors into consideration the lovely fernlike stellar dendrite snowflakes we saw in Austria were probably formed under the following conditions: formed at very low temperatures, in low lying clouds and fell through dry cold air with little wind!

Now lets consider what we are used to here in Ireland!

So this is today’s snow in the west of Ireland!

As I write this I am looking out on a typical “Irish” snow scene… the ground is covered in patchy white snow that is made up of small ball shapes of snow flakes that are a bit wet and sticky. On the plus side these make great snow balls… I can vouch for this one myself as my back is still wet from the pelting I got from my husband as he left for work today (the biggest child in the house)!! So this snow was probably made at lower temperatures in high clouds and melted and froze as it fell to the earth through moist air; this would result in large snow flakes (like small snow balls) made up of a number of small snow crystals joined together. This snow does not tend to last too long, beginning to melt as it hits the ground, making for that wet sticky snow!

SO IS IT TRUE THAT NO TWO SNOW FLAKES ARE IDENTICAL?

The simple answer to this is YES and NO! Although we cannot vouch for every single snowflake that ever existed, science does suggest that the exact shape and structure of each natural snow crystal is unique – so that means YES – no two snow flakes are identical. Especially if you consider the different factors that are involved in creating each snowflake! HOWEVER, for more simple snow crystal structures it can at times be hard to tell the difference between two under a microscope!

WHY IS SNOW WHITE?

When we observe the colour of an object we are actually seeing the colour of light that the object REFLECTS (bounces back)- so green grass, for example, is ABSORBING (taking in) all light expect green light, which it is reflecting. When an object appears white that means it is actually absorbing very little light and reflecting most or all of the light falling on it. This is the case with snow, it’s crystalline structure creates many reflective surfaces making the light that falls on it “bounce back” or be reflected. You can read more about this here.

IS IT EVER TOO COLD TO SNOW?

The simple answer to this is NO, once there is enough water vapour around to make snow, and enough circulating air to transport it then snow can be made at very low temperatures! However, as warmer air can hold more water vapour we tend to get most snowfall at temperatures around freezing point or a bit below.

MAKE YOUR OWN SNOW FLAKE…

Now that you understand all about snow, how it is made and the different shapes and patterns it can take, I thought it would be fun to end with an experiment you can try yourself at home. These are worth the bit of time and effort (and waiting overnight) as the results are really great! Let me know if you try it and how you get on!